key: cord-301167-101lnq4f authors: Liu, Quanjun; Bai, Yunfei; Ge, Qinyu; Zhou, Shixin; Wen, Tian; Lu, Zuhong title: Microarray-in-a-Tube for Detection of Multiple Viruses date: 2007-02-01 journal: Clin Chem DOI: 10.1373/clinchem.2006.071720 sha: doc_id: 301167 cord_uid: 101lnq4f Background: The detection of multiple viruses is important for pathogenic diagnosis and disease control. Microarray detection is a good method, but requires complex procedures for multiple virus detection. Methods: We developed a novel PCR assay, the microarray-in-a-tube system, which integrates multiple PCR processes and DNA microarrays for multiple virus detection. A 5 × 5 oligonucleotide microarray for detecting 4 respiratory tract viruses (severe acute respiratory syndrome–associated coronavirus, influenza A virus, influenza B virus, and enterovirus) with inner controls was arranged on the inner surface of a specially designed Eppendorf cap with a flat, optically transparent window. Results: We were able to perform all detection processes in the encapsulated system without opening the cap. The 4 viruses were successfully amplified by one-step reverse transcription–PCR in the encapsulated tube. After the PCR process, the microarray-in-a-tube was inverted, and the fluorescence-labeled PCR products were directly hybridized on the microarray. Hybridization signals were obtained with an ordinary fluorescent microscope. The sensitivity of the system for virus detection reached 10(2) copies/μL. With the help of inner controls, the system provided reliable results without false negatives and false positives. Conclusions: The microarray-in-a-tube system is a rapid, labor-saving tool for multiple virus detection with several advantages, such as convenience, prevention of cross-contamination of the PCR products, and potential for multiple-gene detection. for use in epidemiology, food safety, and antiterrorism. Two different microfluidic systems, continuous flow and fixed hole, were recently developed for use with PCR or reverse transcription (RT) 1 -PCR, with fluorescence and capillary electrophoresis as the major detection systems for the integrated devices. Although these devices can perform many functions, all of them include high-cost microfabrication techniques and complicated processing steps (1) (2) (3) (4) (5) (6) . Microarray techniques have great potential in highthroughput analysis for genomic screening. Current DNA microarray technology, however, involves the complex and strict execution of multiple experimental processes, and cross-contamination can lead to false results. The combination of microfluidics with a microarray in a single device is one reported method for solving these problems (7) (8) (9) . Severe acute respiratory syndrome (SARS) is a serious infectious disease with global impact (10 ) . A virus, human coronavirus, strain SARS (HCoV-SARS) has been isolated from tissues of patients with SARS (10 -12 ) . The early stage of SARS infection is characterized by fever, dyspnea, lymphopenia, and rapid lung changes visible on x-ray (10, 13 ) , and thus it can be misdiagnosed as influenza. There are 2 prevailing serologic diagnostic methods for SARS, ELISA (14 -16 ) and indirect immunofluorescence assays (12 ) , which are very suitable for the SARS diagnosis during the convalescent phase, when the virus titer is relatively high (17 ) . For early diagnosis of SARS, which is critical for control of the spread of the disease, nucleic acid testing is more sensitive than the above assays (18 ) . Many qualitative PCR assays have been reported (19 -21 ) , and electrochemical (22 ) , electrospray ionization mass spectrometry (23 ) , and microarray techniques (24 ) have been used for sequence-specific detection. We aimed to develop a microarray-in-a-tube that integrates RT-PCR and a DNA microarray for detecting and distinguishing 4 viruses causing human acute respiratory tract infection, SARS coronavirus, influenza A and B viruses, and enterovirus. The microarray-in-a-tube system integrates the microarray and multiple PCR processes in an Eppendorf tube. The system (Fig. 1 ) has 3 parts, which include an optically transparent plastic cap with an oligonucleotide microarray on the inner surface, a black inner vessel that contains hybridization solution, and the body of the Eppendorf tube. The cap, designed for sealing the commercial 200-L Eppendorf tube, was a flat, optically transparent window made of polycarbonate. The inner vessel, which covered half of the circumference within the horizontal section and contained the hybridization solution, was installed in the Eppendorf tube. The microarray-in-a-tube was adapted to a commercial thermocycler. The cap and the vessel were manufactured by plastic injection molding. Microwave-plasma was used to generate a hydrophilic surface on the (hydrophobic) polycarbonate cap so that the agarose film would adhere to its inner surface. The microwave-plasma chamber used here was a sealed quartz glass cylinder (25 ) . The stable ammonia plasma discharge remained for 15 min at a chamber pressure Ͻ60 -70 Pa and with the microwave output power at 100 W. After plasma exposure, the cap board was transferred and immersed in 1 mL/L glutaraldehyde solution for 2 h at room temperature. To immobilize the oligonucleotide probes on the inner surface of the Eppendorf cap, an activated agarose film was prepared on the polycarbonate surface. The method for agarose film fabrication was a modification of a previously reported protocol (26, 27 ) . The 0.5% agarose (Sigma) solution was prepared by mixing and boiling for 5 min. To prepare the agarose film-coated microarray-ina-tube, 10 L of the agarose solution, prewarmed in a 60°C water bath, was poured over each of the specially designed caps. After gelation of the agarose, the cap was dried overnight at 37°C in an oven. The dried cap could be stored at 4°C for future use. Before immobilization of the probes, the agarose films were activated by immersion in 20 mmol/L NaIO 4 (Sigma) in 0.1 mol/L PBS buffer (pH 7.2) for 30 min at room temperature, then thoroughly rinsed with deionized distilled water and dried. The microarray-in-a-tube was stored under nitrogen at 4°C for future use. design and synthesis of dna probes and pcr primers The system was designed to detect and distinguish the SARS coronavirus, influenza A and B viruses, and enterovirus. We designed the primer and the probes based on the GenBank data at the National Center for Biotechnology Information website (http://www.ncbi.nlm.nih.gov/ Genbank/GenbankSearch.html). Three additional probes were designed as controls, one probe for the negative control, one for the inner positive control, which was designed according to the measles virus, and one for the position marker, which was designed for identification of the probe position, as described in Table 1 in the Data Supplement that accompanies the online version of this article at http://www.clinchem.org/content/vol53/ issue1). The position marker was designed for detection of the immobilization of the probes and detection of the position of the probes. The negative control probe was designed for the hybridization background. The most important control was the inner positive control that was used for evaluating the validity of the molecular biology operating processes such as RNA/DNA purification, RT-PCR, microarray hybridization, and hybridization image capture. The primers are shown in Table 2 in the online Data Supplement. The probes and primers were synthesized by TaKaRa Biotechnology (Dalian) Co., Ltd. The new cap with a flat, optically transparent window was designed and fabricated to fit the body of the 200-L Eppendorf tube. The microarray of the DNA probes has been immobilized on the inner side of the window. An inner vessel has been installed inside the Eppendorf tube to store the hybridization solution. setup of the microarray Spotting solutions were obtained by dissolving DNA probes in sodium carbonate buffer (0.1 mol/L, pH 9.0) at the concentration of 80 mol/L The special cap holder was designed to fix the caps on the platform of the spotting robot. Approximately 500 pL of spotting solution was delivered onto the activated agarose film coating the cap inner surface with a 120-m spot diameter and 300-m spacer. The probes were spotted in a pattern as shown in Fig. 2 . After spotting, the agarose film-coated caps were incubated overnight in a humid chamber at room temperature, washed with Tween, 1 mL/L, in deionized distilled water, and dried. The microarray-ina-tube could be used for immediate detection or stored under nitrogen at 4°C for future use. We added 50 L of measles virus to Trizol-treated samples and used the chloroform method for RNA purification. The hybridization buffer should be previously sealed in the system before gene fragment amplification. The hybridization buffer contained 50.0 mmol/L MgCl 2 , 6ϫ SSC buffer, pH 7.2, which was put into the inner vessel. The volume of the hybridization buffer was 25 L. one-step rt-pcr We placed 12.5 L of sample RNA solution into the bottom of the Eppendorf tube and mounted the microarray-in-a-tube on the top of the tube to seal the Eppendorf tube. The specified sequences were then amplified. Amplification was performed with a thermocycler (MJ Research) programmed with 1 cycle at 45°C for 60 min and 95°C for 5 min, followed by 45 cycles of 94°C for 30 s, 52°C for 30 s, and 72°C for 30 s, and then 72°C for 10 min. We When the amplification was complete, the solution temperature was maintained at 95°C for 5 min so that the DNA was denatured. The microarray-in-a-tube was then transferred into ice water. We then turned over the tube and let the 2 solutions mix on the cap of the microarrayin-a-tube with centrifugation (Eppendorf 5804) at 27g for 30 s at room temperature, so that the labeled target DNA would hybridize to the probe immobilized on the cap inner surface. The microarray-in-a-tube should be kept at 37°C during hybridization. After hybridization, the tube was turned over again to remove the solution from the cap. The microarray-in-a-tube was recentrifuged at 500 rpm for 30 s. Then the hybridization image was collected by a fluorescence microscope (Nikon E200) and a CCD camera. The operation steps are shown in File 2 in the online Data Supplement. The data were analyzed with in-house developed software (28 ) to develop a hybridization intensity plot. A typical negative result of the 4 positional marker dots and 4 inner control dots, which was obtained from a sample that contained only measles virus as the inner positive control, is shown in Fig. 3A . The negative image should contain a low fluorescence intensity for the negative probe (NE) and high fluorescence intensity for the position probe (MK) and inner positive probes (PO), as shown in Fig. 3B . The 4 detected viruses and the inner control virus were mixed to demonstrate multivirus detection in a single run (Fig. 3C) . The 4 viruses and the inner control showed similar fluorescence intensities (Fig. 3D) . The respiratory tract virus detection system, based on the microarray-in-a-tube, was tested with standard samples from the National Institute for the Control of Pharmaceutical and Biological Products (NICPBP). In the NICPBP, the standard samples were BJ04 strain for HCoV-SARS, Puerto Rico/8/34/Mount Sinai(H1N1) segment 8 for influenza A, Memphis/12/97-MA for influenza B, and echovirus type 12 (prototype Travis wild-type genome) for enterovirus. A total of 86 samples, which included 20 negative, 60 standard, and 6 clinical serum samples, were detected with our microarray-in-a-tube. Examples of hybridization results and plots of the fluorescent intensities of the samples with single detected virus are shown in Fig. 4 . All results with the microarray-in-a-tube were consistent those with the methods based on RT-PCR and electrophoresis. Neither negative nor false-positive results were found with the microarray-in-a-tube system. The virus could be confirmed from the hybridization image. The detection sensitivity was 10 2 copies/L, and the results were confirmed by the NICPBP (Table 1) . Meanwhile, the Jiangsu CDC provided us with a quantified HCoV-SARS RNA sample (the RealArt HPA coronavirus LC Kit, Artus). The RNA sample contained 7500 copies/L RNA of HCoV-SARS. With a 1/10 to 1/1000 dilution series of the sample, sample concentrations Ͼ75 copies/L were detected. The practical application of most reported PCR microfluidic devices integrated with microarrays is limited because they must be equipped with complicated pumps and valves to drive the reagents, delicate temperaturecontrollers to perform on-chip PCR processes, and optical instruments to read the fluorescent signals. Some devices need high air pressure, special pumps, or special design implementation for solution position control and signal capture (7, 8 ) . The microarray-in-a-tube described here is a simple system that allows the assay to be performed with available instruments, such as a hot-cover thermocy-cler, centrifuge, constant-temperature oven, and conventional fluorescence microscope. The design is based on the conventional Eppendorf tube and features 2 additional parts, the specially designed cap and the inner vessel, which were manufactured by plastic injection and made with polycarbonate plastic. Plastic injection molding is easy to adapt to larger scale fabrication than are conventional photolithographic production techniques (6 ) or laser machining techniques (9 ). The gene amplification method is hypersensitive. A sealed tube for nested-PCR and a 2nd PCR could be performed with a protocol including 2 separated gene amplifications to avoid cross-contamination (29 ) . The disadvantage, however, is that during the assays the amplicon could leak when detected by gel electrophoresis or hybridization analysis. With microelectromechanical system techniques, many other devices are able to prevent the vapor exchange during PCR amplification and DNA hybridization within a closed device (6 -8, 30 ) . These methods are inconvenient to perform, however, whereas the microarray-in-a-tube system was developed to enhance structural simplicity, labor savings, and low cost. In this system, all the steps from gene amplification to image capture could be performed in the sealed device. The system prevents cross-contamination because there is no gene amplicon leakage during any detection process. Asymmetrical RT-PCR production was added in an equal volume hybridization buffer for the 30-min hybridization. Images in A and B are fluorescence images before and after hybridization, respectively. The plots in C are fluorescence intensity before and after hybridization. After capturing the hybridization image, we calculated all the fluorescence intensities with in-house developed software. Three kinds of signal groups could be detected on the microarray for analyzing the reliability of the hybridization results. From the position signals we obtained the immobilized efficiency and the relative position of the probes. In general, because of the effect of hybridization efficiency, the fluorescence intensity of the position probes should be higher than that of hybridization probes. Therefore the fluorescence signals of the hybridization image were classified into 3 groups: the position signal, the negative signal, and the hybridization signals, which include inner control signals. All reliable results of fluorescent hybridization images should contain the above 3 signal groups. In the in-house developed software for the microarray-in-a-tube system, the fluorescence intensities were Ͻ5 for the negative result and Ͼ50 for the position marker. The fluorescence intensity of the inner positive control should be Ͼ20 and less than that of the position marker, otherwise the result should be discarded and the detection should be performed again. If the fluorescence intensity of the detection probes was Ͼ50% of the inner positive control it was considered a positive result. If Ͻ40%, it was considered a negative result. To develop the no-washing microarray in the microarrayin-a-tube, we originally designed molecular beacon probes that differed from the present oligonucleotide probes. Two molecular beacons, modified at the 5Ј-terminal with NH 2 groups and immobilized on activated agarose film, were used for HCoV-SARS detection, as shown in Table 3 in the online Data Supplement). The hybridization buffer contained 50 mmol/L MgCl 2 in 20 mmol/L Tris-HCl (pH 8.0) buffer. Before hybridization, the microarray-in-a-tube system was incubated in the hybridization buffer for 30 min at room temperature. The asymmetrical RT-PCR and hybridized were described as above. Fluorescence images before and after hybridization are shown in Fig. 5 . We were able to use these molecular beacons for HCoV-SARS detection in our microarray-in-a-tube system, but there was relatively high fluorescence background attributable to the unstable stem structure in the molecular beacon probes immobilized on the surface, and the molecular beacon probes are much more expensive than ordinary oligonucleotide probes, which we used successfully for virus detection in our system. In conclusion, the microarray-in-a-tube system is a rapid, labor-saving tool for multiple virus detection with several advantages, such as convenience, prevention of crosscontamination of the PCR products, and potential for multiple-gene detection. 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Other virus culture samples, influenza A and B viruses, enterovirus, and measles rubeola viruses were kindly donated by Nanjing Medical University and Beijing Genomics Institute, Chinese Academy of Science. This study was supported by Projects 60121101 and 60671019 of the National Natural Science Foundation of China and by Grant 2003AA2Z2007 from the National High Tech Program of China.